DE1589239C3 - Circuit arrangement for igniting and / or feeding a gas and / or vapor discharge tube - Google Patents

Description

can act as a transformer primary winding.

The circuit arrangement according to the invention can be used advantageously when a supply of the Discharge tube is provided by a low frequency AC power source, such that the gas and / or vapor tube containing load additionally also directly from a low frequency AC power source is fed. Advantageous are the circuit arrangement according to the invention and the Low frequency source connected to the same load containing the gas and / or vapor discharge tube, wherein the coupling impedance is inductive and at least a part of this coupling impedance is the Stabilization impedance of the discharge tube forms The coupling impedance then has two functions.

Is in cases in which the circuit arrangement according to the invention is in connection with a low-frequency alternating current source is arranged, the supply of discharge tubes with preheated glow electrodes provided, the measure is preferably taken that the impedance in which the input terminals connecting series circuit is inductive and at least part of this impedance is the primary winding a heating current transformer for heating the preheated glow electrodes of the discharge tube In this preferred embodiment, a separate heating current transformer is therefore unnecessary.

When the series circuits bridged by the switch element, the primary winding of the output voltage of the device increasing transformer and the coupling impedance is inductive and at least a part of this coupling impedance forms the stabilizing impedance of the discharge tube and if the transformer has electrically separate windings, the series connection of the Secondary winding of the transformer and the load bridged by an auxiliary capacitor, its The reactance at the frequency of the transformer is less than the reactance at the impedance at which the input terminals are connected bridging series connection at this frequency. If the auxiliary capacitor were not provided, so the impedance in the series connection would have a relatively high reactance value form the high frequency circuit. In the presence of the auxiliary capacitor, a relatively high High frequency current of. the circuit arrangement can be generated.

In the latter case, the secondary winding of the transformer, the load and the circuit containing the auxiliary capacitor or in the circuit of the primary winding of the transformer of the voltage-sensitive circuit element and the capacitance an auxiliary inductance switched on Auxiliary inductance limits the current surges in the two transformer circuits.

The auxiliary inductance is preferably in that part of the circuit of the primary winding of the transformer, of the voltage-sensitive switching element and the capacitance inserted, which is only a part of the high-frequency circuit forms In this solution, the auxiliary inductance only needs a relatively small amount Conduct electricity.

The invention is explained in more detail with reference to the drawing, in which

F i g. 1 a high frequency generator according to the invention,

2 shows a device with a high frequency generator and a low frequency alternating current source connected to the same load,

F i g. Figure 3 shows another device with a high frequency generator and a low frequency AC power source show that are connected to the same load.

In Fig. 1, 1 and 2 denote the terminals of a high-frequency generator. These clamps will by the series connection of a coupling impedance 3, one through the primary winding of a transformer formed inductance 4 and. a capacitor 5 bridged the series connection of the inductance

4 and the capacitor 5 are bridged by a thyristor 6. The control electrode of the thyristor 6 is controlled via an ohmic resistor 7. It connects to the secondary winding of the transformer the series connection of a discharge tube 8 and a stabilizing coil 9. . ,.

The generator works as follows:

A low-frequency network to which terminals 1 and 2 are connected becomes the Capacitor 5 is charged via the coupling impedance 3 and the winding 4 until the voltage is above 4 and 5 is reached in which the circuit element, the Thyristor 6, closes. The capacitor 5 then discharges through the inductance 4 and the circuit element 6. The inductance 4 and the capacitor 5 determine the frequency of the generator. If the thyristor 6 flowing through current reverses its direction affects the circuit element 6 again in the non-conductive State. The capacitor 5 is then charged again via the coupling impedance 3 and the winding 4. To the desired. Number of high frequency oscillations, i.e. the desired number of To achieve wave packets per period of the alternating supply voltage of the generator, the capacitor must

5 are always charged quickly, so that the capacitor will soon be back over the frequency determination contributing impedance 4 can be discharged. This affects the coupling impedance flowing through it Current as follows: The current flowing through this element consists of two components, i.e. the mentioned fast charging current of the capacitor and one in the conductive state of the circuit element occurring current. The first-mentioned component is negligible due to the higher frequency low compared to the current through the coupling impedance in the conductive state of the circuit element, thus compared to the current through the coupling impedance when the latter is connected to the low frequency network is connected as a result of the switch-on phenomenon of the coupling impedance flowing through Current when the circuit element is used for the first time during a positive half cycle of the mains voltage becomes conductive, this current keeps the same direction longer than the duration of a half cycle the mains voltage. As a result, the device can also be driven by alternating current. It should be noted that the lower the voltage at which the circuit element closes, the longer the the Coupling impedance current flowing through it maintains its direction

In a practical case, terminals 1 and 2 of the high frequency generator were connected to a AC power source of 220 V, 50 Hz connected. The high frequency generator served to feed a High-pressure mercury vapor discharge lamp 8, the ignition voltage of which is 600 V and an operating voltage of 125 V. Was 50 Hz. To power the lamp 8 was of

the high-frequency oscillating circuit formed by elements 4, 5 and 6 a high-frequency voltage of sufficient value, e.g. about 2500V peak value 10,000 Hz supplied. The value of the coupling coil 3 was 5 H, the inductance 4 was 2.5 mH and the capacitor 5 had a value of about 0.1 μΚ the peak value the voltage when closing the thyristor 6 was 230 V. This was indicated by a resistor 7 of The peak value of the voltage above the series connection of the capacitor 5 is reached and the inductance 4 in the absence of the thyristor 6 in this case was 300 V.

In this circuit arrangement, the elements 5 and 6 (the latter together with 7) be exchanged. If the high frequency generator is to be fed by a direct current source, the coupling impedance must be formed by a resistor.

In Fig. 2, 2 and 1 again denote the terminals of the device. They are used to connect to a 220 V, 50 Hz network. These clamps are made by the series connection of a coil 3 'and a discharge tube 8 bridged between the tap 10 of this series connection and the terminal 2 is located again a high frequency circuit. This high-frequency circuit corresponds almost to the circuit according to FIG. 1. The differences are the autotransformer with the windings 4 'and 4 "and the isolating capacitor 11. The coupling impedance consists of two parts; H. from the series connection of the coil 3 'and the coil 3 ". The tube 8 is here connected to a low-frequency network via 3 'and to the high-frequency generator via the capacitor 11 connected. The separating capacitor 11 has a high impedance at 50 Hz and a low impedance at the 10,000 Hz of the high frequency generator. The part 3 'of the coupling impedance also acts as a stabilizing impedance for the tube 8. When the Tube 8 with electrodes. 12 and 13 of the preheat type, these can be applied to the secondary windings 14 or 15 of a transformer are connected, the part 3 "of the coupling impedance The high-frequency generator according to FIG. 1 forms the primary winding. 2 serves only as an ignition device for the tube 8.If tube 8 ignites, the voltage between 10 and 2 drops to about 125Veff, i.e. up to about 145 \ Peak value, which is not sufficient to make the thyristor 6 conductive with the working voltage of 230 V. F i g. 3. shows another embodiment in which a lamp 8 is connected to a low-frequency alternating current source and is connected to a high-frequency generator In contrast to the circuit diagram dei F i g. 2 the two current sources are placed in series with one another. A separating capacitor 11 (see FIG. 2) is not required themselves. Corresponding elements are denoted by the same reference numerals as in the previous figures. A decoupling capacitor 16 is also assigned so that the high-frequency currents pass the coil 3 do not need to flow through. The capacitor 16 has a value of about 0.1 μΡ. Furthermore is between the primary winding 4 '"of the transformer and derr circuit element 6 an auxiliary inductance 17 for loading limit the current surges in this circuit and in the Kreit containing the winding 4 "" and the lamp 8 intended.

According to FIG. 3, the high-frequency generator can not only be used when the lamp 8 is ignited, but also when the lamp is ignited Burning the lamp will be effective. This can e.g. B. be accomplished in that the voltage, be which the thyristor 6 closes, is selected lower, z. B. 100 V. For this only the Ohm's who needs of the resistor 7 to be reduced from 20,000 ohms to about 9,000 ohms.

1 sheet of drawings

Claims (6)

Patent claims: 1.Circuit arrangement for igniting and / or feeding a gas and / or vapor discharge tube, soft device includes an inductance and a capacitance, and in which a switch element the mentioned inductance and the capacitance, which are in series, is connected in parallel, and where one the gas and / or vapor discharge tube containing load directly or via a transformer is connected to one or more of the elements of this series circuit, characterized in that, that the input terminals (1,2) of the circuit arrangement are connected in series (3, 4,5) are connected, the at least the mentioned capacitance (5) and an impedance (3) with inductive or resistive character, wherein the switch element (6) is a controlled semiconductor element is, and this controlled semiconductor element becomes conductive, at a voltage across its main electrodes, which is smaller than that when the control circuit of the controlled semiconductor element is interrupted maximum voltage occurring at these main electrodes in the present circuit, and where furthermore the controlled semiconductor element (6) opens at the moment in which the current flows through the controlled semiconductor element is reversed 2. Circuit arrangement according to claim 1, characterized in that the inductance of the the series circuit (4) bridged by the switch element, the primary winding of the output voltage of the device increasing transformer forms 3. Circuit arrangement according to claim 1 or 2, characterized in that the load containing the gas and / or vapor discharge tube (8) is also _{fed directly from a low-frequency alternating current source (I 1} 2) 4. Circuit arrangement according to claim 3, wherein the discharge tube preheatable glow electrodes has, characterized in that the impedance (3 ', 3 ") in that connecting the input terminals (1,2) Series connection is inductive and at least part (3 ", Fig. 2) of this impedance is the primary winding a heating current transformer for heating the preheatable glow electrodes of the discharge tube forms 5. Circuit arrangement according to claims 2 and 3, wherein the transformer is electrically from one another has separate windings, characterized in that the series connection of the secondary winding (4 "") of the transformer and the load (8) bridged by an auxiliary capacitor (16) is its reactance at the frequency of the voltage of the primary winding (4 "") of the transformer (4 '", 4" ") is less than the reactance of the impedance (3', 3") in which the input terminals (1,2) bridging series connection at this frequency. 6. Circuit arrangement according to claim 5, characterized in that in the circuit of the secondary winding (4 "") of the transformer of the load and the auxiliary capacitor (16) or in the Circle of the primary winding (4 '") of the transformer, the switch element (6) and the capacitance (5) a Auxiliary inductance (17) is inserted The invention relates to a circuit arrangement for igniting and / or feeding a gas and / or Vapor discharge tube, which device includes an inductance and a capacitance, and in which a Switch element of the mentioned inductance and capacitance, which are in series, is connected in parallel, and wherein a load containing the gas and / or vapor discharge tube directly or via a Transformer is connected to one or more of the elements of this series circuit. In a device of the type mentioned known according to German patent specification 874 329, the point in time is to which the switch element switches off, largely indefinitely, whereby the known from this Device excited vibrations are not uniform. From »Electronics«, 1965, pp. 71 and 72, there is a transistor inverter known according to the capacitor charge principle, in which a fairly strong influence of the Load occurs on the control of the transistor This can lead to the transistor no longer being controlled will. The circuit arrangement according to the invention avoids these disadvantages and is characterized in that the input terminals of the device are connected by a series circuit which contains at least the mentioned capacitance and an impedance of inductive or ohmic character, the switch element being a controlled semiconductor element, and this controlled semiconductor element being conductive is, at a voltage across its main electrodes that is smaller than the maximum voltage occurring at these main electrodes in the present circuit when the control circuit of the controlled semiconductor element is interrupted, and furthermore the controlled semiconductor element opens at the moment in which the current through the controlled semiconductor element reverses its direction.
In the circuit arrangement according to the invention, the capacitance is charged until the voltage across this capacitor and the inductance in series with it reaches the value at which the switch element closes, the capacitance being discharged until the current flows through the switch element in its direction reversed The capacitance is discharged in a manner known per se via the inductance, which is in series with the capacitance and the switch element. The size of the capacitance and the size of the inductance mentioned influence the rate of discharge of the capacitance in this series connection. In this case, a circuit arrangement according to the invention, the switch element always at the same point in time opens, namely at the zero crossing of the current of the capacitance, are those with this circuit arrangement excited vibrations very evenly. There is also the use of a controlled semiconductor element as a switch element the possibility of igniting the discharge lamp with a high-frequency voltage. “High frequency” should be understood to mean a frequency of more than 1000 Hz. The inductance of the series circuit bridged by the switch element preferably forms the primary winding a transformer increasing the output voltage of the device. This has the advantage that if the output voltage of the switch arrangement is not sufficiently high, the same inductance both as a frequency determining element such as